Wireless audio system and method for wirelessly communicating audio information using the same

ABSTRACT

Embodiments of wireless audio systems and methods for wirelessly communicating audio information are disclosed herein. In one example, a wireless audio system includes a first and a second wireless headphones. The first wireless headphone is configured to receive, from an audio source, audio information using a short-range wireless communication, and in response to successfully receiving the audio information from the audio source, transmit a first error correcting message including an error correcting code generated based on the audio information to a second wireless headphone. The second wireless headphone is configured to receive the audio information from the audio source using the short-range wireless communication, attempt to correct the received audio information based on the first error correcting message, and determine that the received audio information fails to be corrected. In response to the determination, the first wireless headphone is further configured to transmit a second error correcting message including the received audio information to the second wireless headphone.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of priority to Chinese Patent Application No. 201910386827.3, filed on May 10, 2019, which is incorporated herein by reference in its entirety.

BACKGROUND

Embodiments of the present disclosure relate to wireless audio systems.

Loudspeakers, including headphones, have been widely used in daily life. Headphones are a pair of small loudspeaker drivers worn on or around the head over a user's ears, which convert an electrical signal to a corresponding sound.

Wired headphones, however, constrain the users' movement because of the wires (cords), and are particularly inconvenient during exercise. Conventional wireless headphones no longer need the wires between the headphones and the audio sources, but still require the wires between the left and right headphones.

SUMMARY

Embodiments of wireless audio systems and methods for wirelessly communicating audio information are disclosed herein.

In one example, a wireless audio system includes a first wireless headphone and a second wireless headphone. The first wireless headphone is configured to receive, from an audio source, audio information using a short-range wireless communication, and in response to successfully receiving the audio information from the audio source, transmit a first error correcting message comprising an error correcting code generated based on the audio information to a second wireless headphone. The second wireless headphone is configured to receive the audio information from the audio source using the short-range wireless communication, attempt to correct the received audio information based on the first error correcting message and determine that the received audio information fails to be corrected. In response to the determination, the first wireless headphone is further configured to transmit a second error correcting message comprising the received audio information to the second wireless headphone.

In another example, a wireless audio system includes a first wireless headphone and a second wireless headphone. The first wireless headphone is configured to receive, from an audio source, audio information comprising a header and a payload using a short-range wireless communication. The second wireless headphone is configured to receive the audio information from the audio source using the short-range wireless communication and transmit at least one of a first ACK message indicating the second wireless headphone receives the header and the payload of the audio information correctly, a first NACK message indicating the second wireless headphone receives the header, but not the payload, of the audio information correctly, or a second NACK message indicating the second wireless headphone does not receive the header and the payload of the audio information correctly to the first wireless headphone. The first wireless headphone is further configured to receive the at least one of the first ACK message, the first NACK message and the second NACK message, transmit, to the second wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information in response to receiving the first NACK message, and transmit, to the second wireless headphone, a second error correcting message including the received audio information in response to receiving the second NACK message.

In still another example, a method for wirelessly communicating audio information is disclosed. Audio information is received from an audio source using a short-range wireless communication by a first wireless headphone. The method includes, in response to successfully receiving the audio information from the audio source, transmitting, by the first wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information to a second wireless headphone and receiving, by the second wireless headphone, the audio information from the audio source using the short-range wireless communication. The method also includes attempting, by the second wireless headphone, to correct the received audio information based on the first error correcting code and determining, by the second wireless headphone, that the received audio information fails to be corrected. The method further includes, in response to the determination, transmitting, by the first wireless headphone, a second error correcting message comprising the received audio information to the second wireless headphone.

In yet another example, a method for wirelessly communicating audio information is disclosed. Audio information is received from an audio source using a short-range wireless communication by a first wireless headphone. The method also includes receiving, by a second wireless headphone, the audio information from the audio source using the short-range wireless communication and transmitting, by the second wireless headphone to the first wireless headphone, at least one of an ACK message indicating the second wireless headphone receives the header and the payload of the audio information correctly, a first NACK message indicating the second wireless headphone receives the header, but not the payload, of the audio information correctly, or a second NACK message indicating the second wireless headphone does not receive the header nor the payload of the audio information correctly. The method further includes transmitting, by the first wireless headphone to the second wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information in response to the first wireless headphone receives the first NACK message, and transmitting, by the first wireless headphone to the second wireless headphone, a second error correcting message comprising the received audio information in response to the second wireless headphone receives the first NACK message.

This Summary is provided merely for purposes of illustrating some embodiments to provide an understanding of the subject matter described herein. Accordingly, the above-described features are merely examples and should not be construed to narrow the scope or spirit of the subject matter in this disclosure. Other features, aspects, and advantages of this disclosure will become apparent from the following Detailed Description, Figures, and Claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated herein and form part of the specification, illustrate the presented disclosure and, together with the description, further serve to explain the principles of the disclosure and enable a person of skill in the relevant art(s) to make and use the disclosure.

FIGS. 1A and 1B are block diagrams illustrating an exemplary wireless audio system in accordance with various embodiments.

FIG. 2 is a detailed block diagram of the exemplary wireless audio system in FIGS. 1A-1D in accordance with an embodiment.

FIG. 3 is a block diagram illustrating an exemplary wireless headphone in accordance with an embodiment.

FIGS. 4A-4G are timing diagrams of exemplary wireless audio systems in accordance with various embodiments.

FIGS. 5A and 5B are depictions of exemplary BLUETOOTH audio data packets in accordance with an embodiment.

FIG. 6 is a depiction of an exemplary header of an ACK or NACK message in accordance with an embodiment.

FIG. 7 is a flow chart illustrating an exemplary method for wirelessly communicating audio information in accordance with an embodiment.

FIG. 8 is a flow chart illustrating another exemplary method for wirelessly communicating audio information in accordance with an embodiment.

FIG. 9 is a flow chart illustrating still another exemplary method for wirelessly communicating audio information in accordance with an embodiment.

FIG. 10 is a flow chart illustrating yet another exemplary method for wirelessly communicating audio information in accordance with an embodiment.

The presented disclosure is described with reference to the accompanying drawings. In the drawings, generally, like reference numbers indicate identical or functionally similar elements. Additionally, generally, the left-most digit(s) of a reference number identifies the drawing in which the reference number first appears.

DETAILED DESCRIPTION

Although specific configurations and arrangements are discussed, it should be understood that this is done for illustrative purposes only. It is contemplated that other configurations and arrangements can be used without departing from the spirit and scope of the present disclosure. It is further contemplated that the present disclosure can also be employed in a variety of other applications.

It is noted that references in the specification to “one embodiment,” “an embodiment,” “an example embodiment,” “some embodiments,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases do not necessarily refer to the same embodiment. Further, when a particular feature, structure or characteristic is described in connection with an embodiment, it is contemplated that such feature, structure or characteristic may also be used in connection with other embodiments whether or not explicitly described.

In general, terminology may be understood at least in part from usage in context. For example, the term “one or more” as used herein, depending at least in part upon context, may be used to describe any feature, structure, or characteristic in a singular sense or may be used to describe combinations of features, structures or characteristics in a plural sense. Similarly, terms, such as “a,” “an,” or “the,” again, may be understood to convey a singular usage or to convey a plural usage, depending at least in part upon context. In addition, the term “based on” may be understood as not necessarily intended to convey an exclusive set of factors and may, instead, allow for existence of additional factors not necessarily expressly described, again, depending at least in part on context.

True wireless stereo (TWS) headphones (also known as untethered headphones) is a type of wireless headphones that remove the wires between the left and right headphones. In some TWS headphones, a primary wireless headphone can simultaneously communicate with an audio source and a secondary wireless headphone. For example, the audio source transmits data (music, audio, or data packets) to the primary wireless headphone using BLUETOOTH, and the primary wireless headphone then forwards the data to the secondary wireless headphone. This approach can cause the high power consumption of the primary wireless headphone. Also, the physical structures of the human head between the left and right ears can affect the data transmission quality between the primary and secondary wireless headphones, such as causing lagging and/or high latency.

As will be disclosed in detail below, among other novel features, the wireless audio systems disclosed herein can achieve “true wireless stereo” with improved data transmission quality and reduced headphone power consumption. In some embodiments of the present disclosure, the primary wireless headphone establishes a normal communication link with the audio source to receive the audio data (e.g., stereo audio), while the secondary wireless headphone establishes a snoop communication link with the audio source to snoop communications on the normal communication link and receive the audio data from the audio source as well. Having the secondary wireless headphone work in the snoop mode can reduce the power consumption of the primary wireless headphone because the primary wireless headphone no longer needs to forward the audio data to the secondary wireless headphone.

Moreover, one of the primary and secondary wireless headphones, which successfully receives the audio data from the audio source, can transmit a first error correcting message including an error correcting code (ECC) based on the successfully-received audio data to the other wireless headphone, or a second error correcting message including the audio information with or without the ECC. The ECC can be used to correct the error in the audio data received by the other wireless headphone without re-transmitting the audio data. If the first error correcting message fails to correct the error in the audio data received by the other wireless headphone, the second error correcting message including the audio information may be transmitted from the wireless headphone that successfully receives the audio data to the other wireless headphone to correct the error in the audio data received by the other wireless headphone. As the audio information may not necessarily need to be re-transmitted in the error correcting message for correcting error in the audio data received by the other wireless headphone (e.g., the error has been corrected using the first error correcting message), the amount of data of transmitted for error correcting can be reduced, and thus the system reliability and efficiency may be improved.

Additional novel features will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following and the accompanying drawings or may be learned by production or operation of the examples. The novel features of the present disclosure may be realized and attained by practice or use of various aspects of the methodologies, instrumentalities, and combinations set forth in the detailed examples discussed below.

FIG. 1A is a block diagram illustrating an exemplary wireless audio system 100 in accordance with an embodiment. Wireless audio system 100 may include an audio source 102, a primary wireless headphone 104 (e.g., the first wireless headphone), and a secondary wireless headphone 106 (e.g., the second wireless headphone). Audio source 102 may be any suitable device that can provide audio information including, for example, music or voice in the digital or analog format. Audio source 102 may include, but is not limited to, a handheld device (e.g., dumb or smart phone, tablet, etc.), a wearable device (e.g., eyeglasses, wrist watch, etc.), a radio, a music player, an electronic musical instrument, an automobile control station, a gaming console, a television set, a laptop computer, a desktop computer, a netbook computer, a media center, a set-top box, a global positioning system (GPS), or any other suitable device. Primary wireless headphone 104 and secondary wireless headphone 106 may be a pair of loudspeakers that can be worn on or around the head over a user's ears. Primary wireless headphone 104 and secondary wireless headphone 106 may be any electroacoustic transducers that convert an electrical signal (e.g., representing the audio information provided by audio source 102) to a corresponding sound. In some embodiments, each primary wireless headphone 104 and secondary wireless headphone 106 may be an earbud (also known as earpiece) that can plug into the user's ear canal. In some embodiments, primary wireless headphone 104 and secondary wireless headphone 106 may be TWS headphones, which are individual units that are not physically held by a band over the head and/or electrically connected by a cord. Primary wireless headphone 104 and/or secondary wireless headphone 106 may be combined with a microphone to form a headset according to some embodiments. It is understood that although in FIG. 1A, wireless audio system 100 includes both audio source 102 and the pair of primary and secondary wireless headphones 104 and 106, in some embodiments, wireless audio system 100 may include only primary wireless headphone 104 and secondary wireless headphone 106.

As shown in FIG. 1A, bidirectional communications may be established between audio source 102 and primary wireless headphone 104 and between audio source 102 and secondary wireless headphone 106. In some embodiments, a normal communication link may be established between audio source 102 and primary wireless headphone 104 using a short-range wireless communication (e.g., the BLUETOOTH communication or WiFi communication). That is, primary wireless headphone 104 may work in the normal mode. In the normal mode, primary wireless headphone 104 may receive audio information (e.g., in data packets) transmitted by a carrier wave from audio source 102 via the normal communication link. In some embodiments, audio information may be a stream of audio stereo information in the form of compressed or uncompressed stereo samples for first and second audio channels, such as left-channel audio information and right-channel audio information or the like. The normal communication link may be bidirectional such that primary wireless headphone 104 may transmit messages back to audio source 102 in response to the reception of the audio information from audio source 102. As described below in detail, in some embodiments, primary wireless headphone 104 may transmit acknowledgement (ACK) messages to audio source 102 in response to successfully receiving the audio information from audio source 102 or transmit negative acknowledgement (NACK) messages to audio source 102 in response to not successfully receiving the audio information from audio source 102. In some embodiments, the short-range wireless communication between audio source 102 and primary wireless headphone 104 is a unidirectional communication link in which primary wireless headphone 104 receives the audio information from audio source 102, but does not transmit data (e.g., ACK or NACK messages) back to audio source 102.

In some embodiments, a snoop communication link may be established between audio source 102 and secondary wireless headphone 106 using the same short-range wireless communication between audio source 102 and primary wireless headphone 104 (e.g., the BLUETOOTH or WiFi). That is, secondary wireless headphone 106 may work in the snoop mode in which the connection with secondary wireless headphone 106 may not be known by audio source 102. In the snoop mode, secondary wireless headphone 106 may snoop (also known as “listen” or “eavesdrop”) the communications between audio source 102 and primary wireless headphone 104 on the normal communication link. By snooping the communications between audio source 102 and primary wireless headphone 104, secondary wireless headphone 106 may also receive the audio information (e.g., in data packets) transmitted by the carrier wave from audio source 102 via the snoop communication link. The snoop communication link may be bidirectional such that secondary wireless headphone 106 may transmit messages back to audio source 102 in response to the reception of the audio information from audio source 102. As described below in detail, the messages transmitted by secondary wireless headphone 106 may include, for example, ACK messages and NACK messages.

In some embodiments, audio information may be transmitted by audio source 102 according to the BLUETOOTH protocol at the working radio frequency (RF) band between 2,402 MHz and 2,480 MHz or between 2,400 MHz and 2,483.5 MHz (referred to herein as “2.4 GHz”). BLUETOOTH is a wireless technology standard for exchanging data over short distances, and the BLUETOOTH protocol is one example of short-range wireless communication protocols. In one example, audio source 102 may apply the advanced audio distribution profile (A2DP) of the BLUETOOTH protocol for transmitting the audio information. For example, based on the A2DP, a BLUETOOTH audio streaming of music or voice may be streamed from audio source 102 to primary and secondary wireless headphones 104 and 106 over BLUETOOTH connections. In some embodiments, audio information may be transmitted by audio source 102 according to the WiFi protocol at the working RF band of 2.4 GHz or 5 GHz. WiFi is a wireless technology for wireless local area networking based on the IEEE 802.11 standards, and the WiFi protocol (also known as the 802.11 protocol) is another example of short-range wireless communication protocols. It is understood that the transmission of the audio information by audio source 102 may be using any other suitable short-range wireless communication besides BLUETOOTH and WiFi.

As shown in FIG. 1A, to enable secondary wireless headphone 106 work in the snoop mode, primary wireless headphone 104 may transmit, to secondary wireless headphone 106, communication parameters associated with the normal communication link between audio source 102 and primary wireless headphone 104. The communication parameters may include, but are not limited to, the address of audio source 102 (e.g., the IP address or media access control (MAC) address) and the encryption parameters between audio source 102 and primary wireless headphone 104. The transmission of the communication parameters may be carried on by a short-range wireless communication that is the same type as that for transmitting the audio information by audio source 102 or a different type of short-range wireless communication. For example, the short-range wireless communication may be BLUETOOTH communication or WiFi communication. In some embodiments, the transmission of the communication parameters may be at a frequency lower than the frequency used for transmitting the audio information by audio source 102 (e.g., 2.4 GHz). For example, near-field magnetic induction (NFMI) communication may be used for transmitting the communication parameters. NFMI communication is a short-range wireless communication by coupling a tight, low-power, non-propagating magnetic field between devices. NFMI communication can contain transmission energy within the localized magnetic field, which does not radiate into free space. In some embodiments, the carrier wave frequency for NFMI communication is between about 5 MHz and about 50 MHz (e.g., between 5 MHz and 50 MHz), such as between 5 MHz and 40 MHz, between 5 MHz and 30 MHz, between 5 MHz and 20 MHz, between 5 MHz and 10 MHz, between 15 MHz and 50 MHz, between 25 MHz and 50 MHz, between 35 MHz and 50 MHz, and between 45 MHz and 50 MHz. In some embodiments, the carrier wave frequency is about 10 MHz (e.g., 10 MHz) or about 13.56 MHz (e.g., 13.56 MHz).

Upon receiving the communication parameters from primary wireless headphone 104, secondary wireless headphone 106 can establish the snoop communication link with audio source 102 based on the communication parameters. For example, secondary wireless headphone 106 may pretend to be primary wireless headphone 104 so that audio source 102 does not recognize secondary wireless headphone 106 as a newly-connected device and thus, will not disconnect and reconnect with secondary wireless headphone 106.

In response to successfully receiving the audio information (e.g., a BLUETOOTH audio data packet) from audio source 102, primary wireless headphone 104 may be configured to generate an error correcting code (ECC) based on the audio information (e.g., by coding the payload of the BLUETOOTH audio data packet). Primary wireless headphone 104 then may transmit a first error correcting message (ECC MSG) including the ECC to secondary wireless headphone 106. The ECC may include, but not limited to, Reed-Solomon (RS) code, Bose-Chaudhuri-Hocquenghem (BCH) code, etc. In case secondary wireless headphone 106 does not successfully receive the audio information from audio source 102 (e.g., error found in the payload of a BLUETOOTH audio data packet), the ECC contained in the first error correcting message from primary wireless headphone 104 may be used by secondary wireless headphone 106 to correct the audio information (e.g., the error found in the payload of the BLUETOOTH audio data packet). Also, the transmission of the first error correcting message with an ECC can also serve as an ACK message indicative of the successful reception of the audio information by primary wireless headphone 104. Thus, when secondary wireless headphone 106 successfully receives the audio information from audio source 102 based on the ECC from primary wireless headphone 104, secondary wireless headphone 106 may transmit an ACK message to audio source 102 indicative of the successful receptions of the audio information by both primary and secondary wireless headphones 104 and 106, no matter whether primary wireless headphone 104 send another ACK to audio source 102 or not.

In some embodiments, in response to secondary wireless headphone 106 attempts to correct the audio information received from audio source 102 based on the first error correcting message, but fails to do so (e.g., error found in the header of a BLUETOOTH audio data packet), primary wireless headphone 104 may transmit a second error correcting message including the audio information to secondary wireless headphone 106. The audio information contained in second error correcting message from primary wireless headphone 104 may be used by secondary wireless headphone 106 to correct the audio information. When secondary wireless headphone 106 successfully receives the audio information from audio source 102 based on the audio information included in the second error correcting message from primary wireless headphone 104, secondary wireless headphone 106 may still transmit an ACK message to audio source 102 indicative of the successful receptions of the audio information by both primary and secondary wireless headphones 104 and 106, no matter whether primary wireless headphone 104 send another ACK to audio source 102 or not. It is contemplated that, in addition to the audio information, the second error correcting message may additionally include the same ECC as included in the first error correcting message.

As described below in detail, in some embodiments, secondary wireless headphone 106 may transmit an ACK or a NACK to primary wireless headphone 104 indicating whether the audio information is received correctly, and whether the error correcting message (e.g., the first error correcting message) is received correctly.

It is understood that secondary wireless headphone 106 may successfully receive the audio information from audio source 102 based on the ECC or the audio information included in the second error correcting message, either when secondary wireless headphone 106 successfully receives the audio information from audio source 102 without error at the first place (i.e., without the need of correction using the ECC or audio information included in the second error correcting message) or when secondary wireless headphone 106 successfully corrects the audio information from audio source 102 based on the first or the second error correcting message. In whichever case, secondary wireless headphone 106 is considered as “successfully receiving the audio information from audio source 102 based on the ECC.”

The transmission of the first or the second error correcting message may be carried on by a short-range wireless communication that is the same type as that for transmitting the audio information by audio source 102 or a different type of short-range wireless communication. For example, the short-range wireless communication for transmitting the error correcting message may be BLUETOOTH communication or WiFi communication. The WiFi communication may be based on any suitable standards, such as IEEE 802.11b, 802.11d, 802.11g, etc. In some embodiments, the transmission of the communication parameters may be at a frequency lower than the frequency used for transmitting the audio information by audio source 102 (e.g., 2.4 GHz). For example, NFMI communication may be used for transmitting the error correcting message. In some embodiments, the carrier wave frequency for NFMI communication is between about 5 MHz and about 50 MHz (e.g., between 5 MHz and 50 MHz), such as between 5 MHz and 40 MHz, between 5 MHz and 30 MHz, between 5 MHz and 20 MHz, between 5 MHz and 10 MHz, between 15 MHz and 50 MHz, between 25 MHz and 50 MHz, between 35 MHz and 50 MHz, and between 45 MHz and 50 MHz. In some embodiments, the carrier wave frequency is about 10 MHz (e.g., 10 MHz) or about 13.56 MHz (e.g., 13.56 MHz). In some embodiments in which WiFi communication or NFMI communication is used between primary wireless headphone 104 and secondary wireless headphone 106, instead of transmitting the error correcting messages, primary wireless headphone 104 transmits the entire audio information (e.g., the entire BLUETOOTH audio data packets) to secondary wireless headphone 106.

In some embodiments, the reception of the audio information from audio source 102 is not successful at primary wireless headphone 104, primary wireless headphone 104 may transmit a NACK message to audio source 102. In some embodiments, in response to not successfully receiving the audio information from audio source 102, primary wireless headphone 104 may not transmit the NACK message to audio source 102, but instead, transmitting a pseudo error correcting message without the ECC to secondary wireless headphone 106 or not transmitting any message to secondary wireless headphone 106. As to secondary wireless headphone 106, in response to at least one of (i) not successfully receiving the audio information from audio source 102 based on the ECC (indicative of the unsuccessful reception of the audio source by secondary wireless headphone 106 even with the ECC), or (ii) not successfully receiving the error correcting message including the ECC from primary wireless headphone 104 (indicative of the unsuccessful reception of the audio source by primary wireless headphone 104), secondary wireless headphone 106 may transmit a NACK message to audio source 102. It is understood that secondary wireless headphone 106 may not successfully receive the audio information from audio source 102 even after the correction based on the ECC, i.e., the ECC correction at secondary wireless headphone 106 fails.

In some embodiments, instead of generating the ECC and transmitting the error correcting message including the ECC by primary wireless headphone 104, secondary wireless headphone 106 may generate an ECC based on the audio information in response to successfully receiving the audio information from audio source 102 and then transmit a first error correcting message including the ECC or a second error correcting message including the audio information to primary wireless headphone 104. Primary wireless headphone 104 then may receive the first or second error correcting message including the ECC or the audio information from secondary wireless headphone 106 and in response to successfully receiving the audio information from audio source 102 based on the ECC or the audio information included in the second error correcting message, transmit an ACK message to audio source 102.

That is, in implementing the features related to error correcting message (e.g., the first error correcting message and/or the second error correcting message) disclosed herein, the roles of primary and secondary wireless headphones can be switched. In other words, either primary or secondary wireless headphone 104 or 106 can be the party generating and transmitting the ECC and/or the audio information (ECC transmitting headphone), and either primary or secondary wireless headphone 104 or 106 can be the party utilizing the ECC and/or the audio information transmitted from the ECC transmitting headphone for correcting the audio information and transmitting the ACK message to audio source 102 (ECC receiving headphone).

In some embodiments, the ECC transmitting headphone (e.g., the first wireless headphone) and the ECC receiving headphone (e.g., the second wireless headphone) can be dynamically switched based on the signal quality of each of the ECC transmitting headphone and ECC receiving headphone. In some embodiments, the headphone with better signal quality is used as ECC transmitting headphone. That is, the signal quality of the ECC transmitting headphone may be better than the signal quality of the ECC receiving headphone. As a result, the likelihood that the ECC transmitting headphone can successfully receive the audio information from audio source 102 may be increased, thereby transmitting more error correcting messages including the ECC and/or the audio information. With more error correcting messages including the ECC and/or the audio information, the ECC receiving headphone may correct more audio information with errors, thereby reducing the numbers of re-transmission and improving the system reliability. Also, as the headphone with better signal quality is used as ECC receiving headphone, as a result, the likelihood that audio source 102 can successfully receive the ACK and/or NACK messages from the ECC receiving headphone may be increased.

In some embodiments, the ECC transmitting headphone will transmit the first error correcting message to the ECC receiving headphone in response to successfully receiving the audio information from audio source 102. That is being said, no matter whether the ECC receiving headphone receives the audio information correctly or not, the ECC transmitting headphone will transmit the first error correcting message to the ECC receiving headphone anyway.

In some other embodiments, the ECC transmitting headphone will transmit the first error correcting message including ECC but not the audio information, and second error correcting message including the audio information but may or may not including the ECC or transmit no error correcting message to the ECC receiving headphone in response to the ECC transmitting headphone receiving one of a first ACK message, a first NACK message or a second NACK message from the ECC receiving headphone. For example, the ECC transmitting headphone may transmit the first error correcting message in response to receiving the first NACK message. The ECC transmitting headphone may transmit the second error correcting message in response to receiving the second NACK message, and may transmit no error correcting message in response to receiving the first ACK message.

In some embodiments, the ECC receiving headphone may generate and transmit at least one of a first ACK message, a first NACK message or a second NACK message to the ECC transmitting headphone in response to receiving the audio information from audio source 102 correctly, receiving the correct header but not the correct payload of the audio information or without the correct header of the audio information, For example, The ECC receiving headphone may generate and transmit the first ACK message if it receives the audio information correctly. The ECC receiving headphone may generate and transmit the first NACK message if it receives the correct header but not the correct payload of the audio information. And the ECC receiving headphone may generate and transmit the second NACK message if it does not receive the correct header of the audio information.

In some embodiments, the audio information is received by both primary wireless headphone 104 and second wireless headphone 106 from audio source 102 using the first type of short-range wireless communication. Both primary wireless headphone 104 and second wireless headphone 106 determines if it receives the audio information correctly. If the determining headphone determines that it correctly receives the audio information, a first ACK message indicating the determining headphone receives both the header and the payload of the audio information correctly will be transmitted to the other headphone. The determining headphone may further determine if it receives the header of the audio information correctly in response to the determining headphone determines that it does not correctly receive the audio information. If the determining headphone determines it receives the header of the audio information correctly, a first NACK message indicating the determining headphone receives the header, but not the payload of the audio information correctly is generated and transmitted to the other headphone.

In response to the determining headphone receives the header, but not the payload of the audio information correctly, a first error correcting message including the ECC generated by coding a payload of the audio data packet of the audio information but not the audio information is transmitted by the determining headphone in response to the determining headphone receives the header, but not the payload, of the audio information correctly. A second NACK message indicating the determining headphone does not receive the header nor the payload of the audio information correctly is generated and transmitted to the other headphone if the determining headphone determines it does not receive the header of the audio information correctly. A second error correcting message including the audio information is transmitted by the determining headphone in response to the other headphone receives the second NACK. In some embodiments, the second error correcting message may additionally include the ECC generated by coding a payload of the audio data packet.

FIG. 1B is a block diagram illustrating exemplary wireless audio system 100 in accordance with another embodiment. The same functions of audio source 102, primary wireless headphone 104, and secondary wireless headphone 106 that have been described above with respect to FIG. 1A will not be repeated with respect to FIG. 1B. Different from the example of FIG. 1A, in this example, when primary wireless headphone 104 successfully receives part of the audio information (e.g., the header of a BLUETOOTH audio data packet) but fails to correctly receive other parts of the audio information (e.g., the payload of the BLUETOOTH audio data packet), primary wireless headphone 104 may transmit a first error correcting message (ECC MSG 1) without an ECC to secondary wireless headphone 106. In this situation, when secondary wireless headphone 106 successfully receives the audio information from audio source 102 as well as the first error correcting message without the ECC from primary wireless headphone 104, secondary wireless headphone 106 may generate an ECC based on the audio information and transmit a second error correcting message (ECC MSG 2) including the ECC to primary wireless headphone 104. Primary wireless headphone 104 then may correct the part of the audio information that fails to be correctly received without the need of re-transmission.

In some embodiments, the ECC transmitting headphone that transmits the first error correcting message and the ECC receiving headphone that receives the first error correcting message can be switched between primary and secondary wireless headphones 104 and 106.

In some embodiments, ECC may be encoded by a wireless headphone (e.g., primary wireless headphone 104 and/or secondary wireless headphone 106) that correctly receives the audio information from audio source 102 using the correctly received audio information (e.g., audio 1 in FIG. 1A). For example, primary wireless headphone 104 and secondary wireless headphone 106 may both receive the same audio information from audio source 102. One or both of primary and secondary wireless headphone 104 and 106 may correctly receive the audio information. The correctly receiving wireless headphone may generate the first ECC by encoding the correctly received audio information (e.g., using an encoder) and may transmit the first ECC to the other wireless headphone. The other wireless headphone may correct the wrongly received audio information (e.g., audio 2 in FIG. 1A which has errors in the audio data packet) by decoding the first ECC and the wrongly received audio information (e.g., using a decoder). In some embodiments, if the wrongly received audio information cannot be corrected by the first ECC, a second ECC message may be generated and transmitted by the correctly receiving wireless headphone. In some embodiments, the second ECC message may include the correctly received audio information but not the first ECC. In some other embodiments, the second ECC message may include both the correctly received audio information and the first ECC.

FIG. 2 is a detailed block diagram of exemplary wireless audio system 100 in FIGS. 1A-1B in accordance with an embodiment. Audio source 102 in this example includes an antenna 202, a radio-frequency (RF) module 204 and a physical layer module 206. It is understood that additional module(s) may be included in audio source 102, either in the same integrated circuit (IC) chip in which RF module 204 and physical layer module 206 are formed or in a separate IC chip.

Antenna 202 may include an array of conductors for transmitting and receiving radio waves at one or more RF bands corresponding to RF module 204. For example, antenna 202 may transmit audio information modulated by a carrier wave using RF module 204. As described above, the audio information may be any music and/or voice information provided by audio source 102. For example, the audio information may be a stream of audio stereo information in the form of compressed or uncompressed stereo samples for first and second audio channels, such as left-channel audio information and right-channel audio information or the like. In some embodiments, the audio information may be mono audio information in a single audio channel or audio information in more than two separate audio channels (e.g., left, central, and right channels). Antenna 202 may also receive the messages modulated by a carrier wave. For example, the messages may be any messages used for acknowledging the reception of the audio information by primary wireless headphone 104 or secondary wireless headphone 106, such as ACK and NACK messages.

RF module 204 and physical layer module 206 may be in the same IC chip that implements a short-range wireless communication protocol, such as the BLUETOOTH protocol or WiFi protocol. RF module 204 may be configured to modulate the audio information using the carrier wave at a frequency, for example, at 2.4 GHz for BLUETOOTH or WiFi communication, and transmit the audio information at the frequency via antenna 202. RF module 204 may be further configured to receive and demodulate the messages and/or the audio information (e.g., the voice information during voice calls) from the carrier wave at the same frequency, for example, at 2.4 GHz. Physical layer module 206 may be configured to generate the physical link (baseband) between audio source 102 and primary wireless headphone 104 (and secondary wireless headphone 106 even though audio source 102 may not be aware of the connection with secondary wireless headphone 106) according to the short-range wireless communication protocol. For example, physical layer module 206 may generate baseband packets (e.g., BLUETOOTH packets) based on the music and/or voice data (payload) and perform error correction using any known methods, such as forward error correction (FEC) and automatic repeat request (ARQ).

In some embodiments, the transmission of the audio information may occur at the audio data packet level in time slots. For example, according to the standard BLUETOOTH protocol, the physical channel of the BLUETOOTH connection is divided into time slots, each of which has the same duration (e.g., 625 μs). RF module 204 in conjunction with antenna 202 may transmit an audio data packet (N) in a time slot (N). Based on the receptions of the audio data packet (N) in the time slot (N) at primary wireless headphone 104 and secondary wireless headphone 106, in the subsequent time slot (N+1), RF module 204 in conjunction with antenna 202 may receive a message from primary wireless headphone 104 or secondary wireless headphone 106 alone, or messages from both primary wireless headphone 104 and secondary wireless headphone 106, which are generated in response to the reception status of the audio data packet (N) in the time slot (N). It is understood that additional components, although not shown in FIG. 2, may be included in audio source 102.

Primary wireless headphone 104 in this example may include a wireless transceiver (primary wireless transceiver) configured to receive the audio information transmitted by audio source 102 and transmit or receive error correcting messages (with or without an ECC and/or the audio information) in response to the reception of the audio information to audio source 102. The wireless transceiver may be further configured to transmit the communication parameters to secondary wireless headphone 106. Primary wireless headphone 104 may include other components, such as an enclosure, speakers, and a microphone (not shown). Primary wireless transceiver may include an antenna 208, a first RF module 210, a second RF module 212, a physical layer module 214, a MAC layer module 216, a host controller interface (HCI) 218, and a control module 220. Some or all of the modules mentioned above may be integrated in the same IC chip to reduce the chip size and/or power consumption. Primary wireless headphone 104 may present at least part of the audio information received from audio source 102 to the user via one of the user's ear. For example, the speaker of primary wireless headphone 104 may play music and/or voice based on the entire audio information or one audio channel of the audio information.

Antenna 208 may include an array of conductors for transmitting and receiving radio waves at two or more RF bands corresponding to first RF module 210 and second RF module 212. First RF module 210 may be configured to receive, from audio source 102, audio information and transmit, to audio source 102, messages (e.g., ACK and NACK messages) via antenna 208. Second RF module 212 may be configured to transmit, to secondary wireless headphone 106, the communication parameters and error correcting messages (when primary wireless headphone 104 works as the ECC transmitting headphone) via antenna 208. In some embodiments, second RF module 212 may be further configured to receive, from secondary wireless headphone 106, error correcting messages (when primary wireless headphone 104 works as the ECC receiving headphone) via antenna 208.

In some embodiments, the first frequency used for the communications between audio source 102 and primary wireless headphone 104 is a “high” RF, such as 2.4 GHz used in BLUETOOTH or WiFi communication; the second frequency used for the communications between primary wireless headphone 104 and secondary wireless headphone 106 is a “low” RF, such as between 5 MHz and 50 MHz for NFMI communication. Both first RF module 210 and second RF module 212 may implement substantially the same short-range wireless communication protocol for short-range wireless communications at different RF bands. For example, first RF module 210 may implement a first short-range wireless communication protocol (e.g., the BLUETOOTH protocol or WiFi protocol), and second RF module 212 may implement a second short-range wireless communication protocol amended from the first short-range wireless communication protocol (e.g., the amended BLUETOOTH or amended WiFi protocol). The second short-range wireless communication protocol may be substantially the same as the first short-range wireless communication protocol except for the carrier wave frequency (and any specification related to the carrier wave frequency).

In some embodiments, first RF module 210 may operate at about 2.4 GHz (e.g., 2.4 GHz). In some embodiments, second RF module 212 may operate between about 5 MHz (e.g., 5 MHz) and about 50 MHz (e.g., 50 MHz) for NFMI communication. For example, second RF module 212 may operate at about 10 MHz (e.g., 10 MHz). In some embodiments, second RF module 212 may implement the frequency-hopping spread spectrum (FHSS) technique, such that the second frequency (low RF) may include a plurality of frequencies based on FHSS. For example, second RF module 212 may implement the amended BLUETOOTH protocol and use the FHSS specification in the amended BLUETOOTH protocol. FHSS can further reduce signal interference.

Physical layer module 214 may be configured to generate the physical links (baseband) between audio source 102 and primary wireless headphone 104 according to the short-range wireless communication protocol and the amended short-range wireless communication protocol used by first RF module 210 and second RF module 212, respectively. For example, physical layer module 214 may generate baseband packets (e.g., BLUETOOTH packets) based on the music and/or voice data (payload) and perform error correction using any known methods, such as FEC and ARQ. MAC layer module 216 may be configured to generate the logical data channel links between audio source 102 and primary wireless headphone 104 according to the short-range wireless communication protocol and between primary wireless headphone 104 and secondary wireless headphone 106 according to the amended short-range wireless communication protocol used by first RF module 210 and second RF module 212, respectively. For example, MAC layer module 216 may generate link control channel, link manager channel, user asynchronous channel, user isochronous channel, and user synchronous channel based on the BLUETOOTH protocol (and the amended BLUETOOTH protocol). HCI 218 may be configured to provide a common interface to physical layer module 214 and MAC layer module 216 and access to hardware status and control registers. For example, when implementing the BLUETOOTH protocol (and the amended BLUETOOTH protocol), HCI 218 may provide a uniform method of accessing the BLUETOOTH baseband capabilities.

In some embodiments, the error correction messages are transmitted based on a standard BLUETOOTH protocol in network layers above a physical layer, for example, by MAC layer module 216 and HCI 218, and are transmitted based on an amended BLUETOOTH protocol in the physical layer, for example, by physical layer module 214. For example, the error correcting messages can be transmitted at a higher symbol rate than the standard BLUETOOTH protocol in the physical layer, for example, by physical layer module 214 according to the amended BLUETOOTH protocol. In some embodiments, the symbol rate for transmitting the error correcting messages in the physical layer is 2M/s, which is higher than the standard BLUETOOTH symbol rate of 1M/s. By increasing the symbol rate in the physical layer for the error correcting messages, more ECCs can be transmitted, thereby improving the error correction capability.

As described above, primary wireless headphone 104 can either an ECC transmitting headphone or an ECC receiving headphone. In some embodiments, control module 220 may control primary wireless headphone 104 to switch between the ECC transmitting headphone and the ECC receiving headphone. In some embodiments, control module 220 may determine whether to switch the ECC headphone mode of primary wireless headphone 104 based on one or more parameters associated with primary wireless headphone 104 and/or secondary wireless headphone 106, such as signal quality. In one example, control module 220 may determine whether the signal quality (e.g., signal-to-noise ratio (SNR) or received signal strength indicator (RSSI)) is above a threshold and cause primary wireless headphone 104 to switch to a different ECC headphone mode. That is, in some embodiments, the wireless headphone with the relatively poor signal quality may be used as the ECC transmitting headphone, while the wireless headphone with the relatively good signal quality may be used as the ECC receiving headphone, so that the ACK/NACK messages transmitted by the ECC receiving headphone can be more easily received by audio source 102. In some embodiments, the wireless headphone with the relatively poor signal quality may be used as the ECC receiving headphone, while the wireless headphone with the relatively good signal quality may be used as the ECC transmitting headphone, so that more error correcting messages with ECCs can be generated to reduce the times of re-transmission.

Control module 220 may be further configured to control the generation of the ECC based on the successfully received audio information when primary wireless headphone 104 is working as an ECC transmitting headphone or control the correction of the audio information based on the received ECC when primary wireless headphone 104 is working as an ECC receiving headphone. When working as the ECC receiving headphone, control module 220 may be further configured to determine whether to transmit an ACK message or a NACK message to audio source 102 depending on various factors, including (1) whether an error correcting message is received from secondary wireless headphone 106 (the ECC transmitting headphone), (2) whether the received error correcting message includes an ECC, (3) whether the audio information received by primary wireless headphone 104 needs correction, and (4) whether the correction of the audio information based on the ECC is successful.

Secondary wireless headphone 106 in this example may include a wireless transceiver (secondary wireless transceiver) configured to receive (snoop) the audio information transmitted by audio source 102 and transmit or receive error correcting messages (with or without an ECC) in response to the reception of the audio information to audio source 102. The wireless transceiver may be further configured to receive the communication parameters from primary wireless headphone 104. Secondary wireless headphone 106 may include other components, such as an enclosure, speakers, and a microphone (not shown). Secondary wireless transceiver may include an antenna 222, a first RF module 224, a second RF module 226, a physical layer module 228, a MAC layer module 230, an HCI 232, and a control module 234. Some or all of the modules mentioned above may be integrated in the same IC chip to reduce the chip size and/or power consumption. Secondary wireless headphone 106 may present at least part of the audio information to the user via one of the user's ear. For example, the speaker of secondary wireless headphone 106 may play music and/or voice based on the audio information or one audio channel of the audio information.

In this example, secondary wireless headphone 106 has the same hardware structures as primary wireless headphone 104. The functions of each module mentioned above in secondary wireless headphone 106 are the same as the counterparts in primary wireless headphone 104 and thus, will not be repeated. Different from primary wireless headphone 104, secondary wireless headphone 106 in this example works in the snoop mode, so that audio source 102 may not recognize the connection with secondary wireless headphone 106. To enable secondary wireless headphone 106 to work in the snoop mode, in some embodiments, second RF module 212 of primary wireless headphone 104 may transmit, to second RF module 226 of secondary wireless headphone 106, one or more communication parameters associated with the short-range wireless communication protocol used between audio source 102 and primary wireless headphone 104. The communication parameters may include any parameters necessary for enabling secondary wireless headphone 106 to snoop the communications between audio source 102 and primary wireless headphone 104, such as the address of audio source 102 (e.g., the IP address or MAC address) and the encryption parameters used between audio source 102 and primary wireless headphone 104.

As described above, similar to control module 220 of primary wireless headphone 104, control module 234 of secondary wireless headphone 106 may control secondary wireless headphone 106 to switch between the ECC transmitting headphone and the ECC receiving headphone. The switch may be determined based on one or more parameters, such as the relative signal quality between primary wireless headphone 104 and secondary wireless headphone 106. For example, both control modules 220 and 234 may work together to switch the ECC headphone modes of primary wireless headphone 104 and secondary wireless headphone 106 to improve the overall performance of the pair of wireless headphones 104 and 106 as described above in detail.

Control module 234 may be further configured to control the generation of the ECC based on the successfully received audio information when secondary wireless headphone 106 is working as an ECC transmitting headphone or control the correction of the audio information based on the received ECC when secondary wireless headphone 106 is working as an ECC receiving headphone. When working as the ECC receiving headphone, control module 234 may be further configured to determine whether to transmit an ACK message or a NACK message to audio source 102 depending on various factors, including (1) whether an error correcting message is received from primary wireless headphone 104 (the ECC transmitting headphone), (2) whether the received error correcting message includes an ECC, (3) whether the audio information received by secondary wireless headphone 106 needs correction, and (4) whether the correction of the audio information based on the ECC is successful.

Although in FIG. 2, the same physical layer module, MAC layer module, and HCI are used for both first and second RF modules 210 and 212 or 224 and 226, it is understood that in some embodiments, each of first and second RF modules 210 and 212 or 224 and 226 may have its own physical layer module, MAC layer module, and/or HCI. In other words, each of primary and secondary wireless headphones 104 and 106 may include two physical layer modules, two MAC layer modules, and/or two HCIs. As a result, two different types of short-range wireless communications can be implemented by each of primary and secondary wireless headphones 104 and 106. In some embodiments, second RF modules 212 and 226 and their respective physical layer modules, MAC layers modules, and/or HCIs are used to implement WiFi communication or NFMI communication between primary and secondary wireless headphones 104 and 106 for transmitting and receiving error correcting messages.

FIG. 3 is a block diagram illustrating exemplary wireless headphone 104 or 106 in accordance with an embodiment. In this example, each of primary wireless headphone 104 and secondary wireless headphone 106 includes an RF front-end 302, an analog-to-digital (A/D) converter 304, a demodulation module 306, a clock frequency module 308, a phase-locked loop (PLL) 310, a clock oscillator 312, a frequency divider 314, and a timing module 316. RF front-end 302 may be operatively coupled to an antenna and configured to receive the RF signals, such as audio signals representing the audio information described above in detail. RF front-end 302 may include an antenna switch, low-noise amplifier (LNA), power amplifier (PA), filter, etc. A/D converter 304 may be operatively coupled to RF front-end 302 and configured to convert an audio signal from an analog signal to a digital signal and provide the digital audio signal to demodulation module 306 that is operatively coupled to A/D converter 304. The A/D conversion may be performed by A/D converter 304 based on an A/D sampling rate determined by frequency divider 314.

In some embodiments, primary wireless headphone 104 and secondary wireless headphone 106 may not communicate directly except for transmitting the communication parameters and error correction messages as described above. Primary wireless headphone 104 and secondary wireless headphone 106 may be synchronized via their communications with audio source 102. The local clocks of each of primary wireless headphone 104 and secondary wireless headphone 106 may be synchronized with the remote clock of audio source 102 and thus, are synchronized with one another. By indirectly synchronizing primary wireless headphone 104 and secondary wireless headphone 106 via audio source 102, the sound can be simultaneously played by both primary wireless headphone 104 and secondary wireless headphone 106.

FIGS. 4A-4G are timing diagrams of exemplary wireless audio systems in accordance with various embodiments. As described above, error correcting messages may be transmitted from an ECC transmitting headphone to an ECC receiving headphone. As described above, in some embodiments, each of the time slots (e.g., N and N+1) has the same duration, for example, 625 μs for BLUETOOTH communication. As shown in FIG. 4A, in a first time slot (N), the audio source transmits an audio data packet (e.g., a BLUETOOTH audio data packet), and each of the ECC transmitting and receiving headphones receives the audio data packet. In the same time slot (N), the ECC transmitting headphone transmits an error correcting message including an ECC or a pseudo error correcting message without an ECC depending on whether the ECC transmitting headphone successfully receives the audio data packet in time slot (N). In the same time slot (N), the ECC receiving headphone receives the error correcting message or pseudo error correcting message from the ECC transmitting headphone.

In a second time slot (N+1) immediately subsequent to the first time slot (N), the ECC receiving headphone may transmit an ACK message or a NACK message to the audio source depending on whether it successfully receives the audio data packet based on the error correcting message in the first time slot (N). In a first situation, if in the first time slot (N), the ECC receiving headphone receives the error correcting message including the ECC from the ECC transmitting headphone and corrects the error in the audio data packet based on the ECC (i.e., successfully receiving the audio data packet after the correction), then in the second time slot (N+1), the ECC receiving headphone transmits an ACK message to the audio source. In a second situation, if in the first time slot (N), the ECC receiving headphone receives the error correcting message including the ECC from the ECC transmitting headphone and does not find any error in the audio data packet (i.e., successfully receiving the audio data packet without the correction), then in the second time slot (N+1), the ECC receiving headphone transmits an ACK message to the audio source as well. In a third situation, if in the first time slot (N), the ECC receiving headphone receives the error correcting message including the ECC from the ECC transmitting headphone and fails to correct the error in the audio data packet using the ECC (i.e., not successfully receiving the audio data packet), then in the second time slot (N+1), the ECC receiving headphone transmits a NACK message to the audio source. In a fourth situation, if in the first time slot (N), the ECC receiving headphone receives the pseudo error correcting message without the ECC from the ECC transmitting headphone or does not receive any error correcting message (i.e., not successfully receiving the error correcting message including the ECC), then in the second time slot (N+1), the ECC receiving headphone transmits a NACK message to the audio source as well.

In some embodiments, if in the first time slot (N), the ECC transmitting headphone does not successfully receive the audio data packet from the audio source, then in the second time slot (N+1), the ECC transmitting headphone transmits an ACK message to the audio source as well.

It is understood that in FIG. 4A, each audio data packet is transmitted within a single time slot, e.g., the first time slot (N), for example according to BLUETOOTH Hands Free Profile (HFP). In the time slot in which the audio data packet is transmitted by the audio source, the audio data packet and the error correcting message can share the same time slot. For example, the audio data packet may be transmitted prior to the error correcting message in the same time slot. In some embodiments, each audio data packet can be transmitted within multiple time slots, for example according to BLUETOOTH A2DP.

As shown in FIG. 4B, the audio data packet is transmitted from the audio source to each of the ECC transmitting and receiving headphones in N slots, and the error correcting message or pseudo error correcting message is transmitted from the ECC transmitting headphone to the ECC receiving headphone at the end of the last one of N slots (Nth slot). That is, at least part of the audio data packet is transmitted in the same slot (Nth slot) as the error correcting message. Similar to the example in FIG. 4A, in a time slot immediately subsequent to the last one of N slots, e.g., (N+1)th slot, the ECC receiving headphone transmits an ACK message or a NACK message to the audio source as described above in detail.

It is further understood that in some embodiments, the error correcting message may be transmitted in more than one time slot. In the case in which the audio data packet and the error correcting message are transmitted in N time slots (e.g., 3 or 5 time slots), the specific numbers of time slots within the N time slots used for transmitting the respective audio data packet and the error correcting message are not limited as long as the audio data packet is transmitted prior to the error correcting message in the N time slots. Thus, the error correcting message may be transmitted in the last one or more time slots of the N time slots.

In some embodiments, another type of error correcting message without an ECC may be transmitted from the ECC transmitting headphone to the ECC receiving headphone when the ECC transmitting headphone successfully receives the header of the audio data packet but fails to correctly receive the payload of the audio data packet. FIGS. 5A and 5B are depictions of exemplary BLUETOOTH audio data packets in accordance with an embodiment. Both BLUETOOTH audio data packets in FIGS. 5A and 5B include an access code, a header, and a payload in which the actual audio information is coded.

FIG. 5B illustrates an enhanced data rate BLUETOOTH audio data packet, which further includes guard, synchronization, and trailer fields. The payload of the enhanced data rate BLUETOOTH audio data packet may be transmitted at a higher symbol rate than the standard BLUETOOTH symbol rate by using different modulation technique (DPSK) than the header (GFSK). As described above, the ECC can be coded based on the actual audio information in the payload of a BLUETOOTH audio data packet using RS code, BCH code, etc.

As described above, FIG. 6 is a depiction of an exemplary header of an ACK or NACK message in accordance with an embodiment. In some embodiments, the header may include a logical transmission address, types of packets (a 4-bit code specifies which packet type is used), a flow control of packets, an acknowledge indication bit (ARQN a 1-bit acknowledgement used to inform the source of successful transfer of payload data), a SEQN that provides a sequential numbering scheme to order the data packet stream and a header-error-check for checking the header's integrity. In some embodiments, the ARQN is indicative of whether the packet is an ACK message or a NACK message. The packet is an ACK message if ARQN is 1, as shown in FIG. 6. The packet is a NACK message if ARQN is 0.

As shown in FIG. 4C, in a first time slot (N), if the ECC transmitting successfully receives the header of the audio data packet but fails to correctly receive the payload of the audio data packet, it transmits a first error correcting message without an ECC to the ECC receiving headphone. In the second time slot (N+1) immediate subsequent to the first time slot (N), the ECC receiving headphone transmits a second error correcting message including an ECC generated by coding the payload of the audio data packet received by the ECC receiving headphone in the first time lot (N). By receiving the second error correcting message including the ECC, in the second time slot (N+1), the ECC transmitting headphone may correct the errors in the payload of the audio data packet. Similar to the example in FIG. 4A, in the second time slot (N+1), the ECC receiving headphone transmits an ACK message or a NACK message to the audio source as described above in detail. It is understood that although FIG. 4C shows the transmission of an audio data packet in a single time slot, the scheme can be expanded to situations in which the audio data packet is transmitted over multiple time slots, for example according to BLUETOOTH A2DP as described above with respect to FIG. 4B.

FIGS. 4D and 4E are timing diagrams of an exemplary wireless audio system implemented in another schedule. In this example, the ECC transmitting headphone, as opposed to the ECC receiving headphone, transmits the ACK or NACK message to the audio source. As shown in FIG. 4D, in the first time slot (N), the ECC transmitting headphone successfully receives the audio data packet and thus, transmits an error correcting message including an ECC in the same time slot (N) to the ECC receiving headphone. In the same time slot (N), the ECC receiving headphone transmits a status message (STAT) to the ECC transmitting headphone, which indicates whether the ECC receiving headphone successfully receives the audio data packet based on the ECC received from the ECC transmitting headphone. For example, the status message may indicate that the reception of the audio data packet at the ECC receiving headphone is successfully either because no error is found at the first place or the error has been corrected using the ECC. The status message may indicate that reception of the audio data packet at the ECC receiving headphone is unsuccessfully even after the correction using the ECC. In the immediately subsequent slot (N+1), the ECC transmitting headphone transmits an ACK message or a NACK message to the audio source based on the status message received from the ECC receiving headphone.

As shown in FIG. 4E, in the first time slot (N), the ECC transmitting headphone does not successfully receive the audio data packet and thus, transmits a status message indicative of such failure to the ECC receiving headphone. In the same time slot (N), the ECC receiving headphone may transmit an error correcting message including an ECC if it successfully receives the audio data packet or a status message indicative of its failure to successfully receive the audio data packet to the ECC transmitting headphone. If the ECC transmitting headphone receives the error correcting message including the ECC from the ECC receiving headphone in the first time slot (N) and corrects the audio data packet based on the ECC, then in the immediate subsequent time slot (N+1), the ECC transmitting headphone transmits an ACK message to the audio source. If the ECC transmitting headphone receives the error correcting message including the ECC but fails to correctly correct the audio data packet based on the ECC or if the ECC transmitting headphone receives the status message indicative of the ECC receiving headphone's failure to successfully receive the audio data packet, then in the immediate subsequent time slot (N+1), the ECC transmitting headphone transmits a NACK message to the audio source.

It is understood that although FIGS. 4D and 4E show the transmission of an audio data packet in a single time slot, the scheme can be expanded to situations in which the audio data packet is transmitted over multiple time slots, for example according to BLUETOOTH A2DP as described above with respect to FIG. 4B. In some embodiments, each time slot may be a standard BLUETOOTH time slot having the same duration (e.g., 625 μs), and the messages described in FIGS. 4D and 4E are communicated using WiFi communication such that multiple messages can be communicated in a single standard BLUETOOTH time slot.

FIGS. 4F and 4G, are further timing diagrams of an exemplary wireless audio system implemented in another schedule. In this example, in a first time slot (N), the audio source transmits an audio data packet (e.g., a BLUETOOTH audio data packet), and each of the ECC transmitting and receiving headphones receives the audio data packet. In the same time slot (N), the ECC transmitting headphone transmits a first error correcting message including an ECC or a pseudo error correcting message without an ECC depending on whether the ECC transmitting headphone successfully receives the audio data packet in time slot (N).

As shown in FIG. 4F, in the same time slot (N), the ECC receiving headphone receives the first error correcting message or pseudo error correcting message from the ECC transmitting headphone. In a second time slot (N+1), the ECC receiving headphone may transmit an ACK message or a NACK message to the ECC transmitting headphone depending on whether it successfully receives the audio data packet based on the first error correcting message in the first time slot (N). If the ECC receiving headphone fails to correctly receive the audio data packet based on the first error correcting message, in the third time slot (N+2), the ECC transmitting headphone may transmit a second error correcting message including the audio information to the ECC receiving headphone. In the same time slot, the ECC receiving headphone receives the second error correcting message. In some embodiments, the second error correcting message may also include the same ECC as the first error correcting message.

As shown in FIG. 4G, if in the second time slot (N+1) the ECC transmitting headphone does not receive the ACK or the NACK message from the receiving headphone, in the third time slot (N+2), the ECC transmitting headphone may re-transmit the first error correcting message including ECC to the ECC receiving headphone until (i) the ECC transmitting headphone receives the ACK message or (ii) the first error correcting message has been re-transmitted for more than a predetermined times (e.g., 3 times, 5 times, 10 times etc.).

In some embodiments, if in the first time slot (N), the ECC transmitting headphone does not successfully receive the audio data packet from the audio source, then in the second time slot (N+1) or the third time slot (N+2), upon successfully receives the audio data packet in that time slot, the ECC transmitting headphone transmits an ACK message to the audio source as well.

FIG. 7 is a flow chart illustrating an exemplary method 700 for wirelessly communicating audio information in accordance with an embodiment. Method 700 can be performed by processing logic that can comprise hardware (e.g., circuitry, dedicated logic, programmable logic, microcode, etc.), software (e.g., instructions executing on a processing device), or a combination thereof. It is to be appreciated that not all operations may be needed to perform the disclosure provided herein. Further, some of the operations may be performed simultaneously, or in a different order than shown in FIG. 7, as will be understood by a person of ordinary skill in the art.

Method 700 shall be described with reference to FIGS. 1A, 1B, and 2. However, method 700 is not limited to that exemplary embodiment. Starting at 702, a first type of short-range wireless communication, such as BLUETOOTH communication, is established with an audio source. In some embodiments, the short-range wireless communication is established between primary wireless headphone 104 and audio source 102. At 704, communication parameters indicative of the short-range wireless communication are transmitted. In some embodiments, the communication parameters are transmitted from primary wireless headphone 104 to secondary wireless headphone 106 using the first type of short-range wireless communication, such as BLUETOOTH communication, or a second type of short-range wireless communication, such as WiFi communication or NFMI communication. In some other embodiments, the communication parameters may also be transmitted from secondary wireless headphone 106 to primary wireless headphone 104 using the first type or the second type of short-range wireless communication.

At 706, audio information is received by an ECC transmitting headphone from the audio source using the first type of short-range wireless communication, such as BLUETOOTH communication. In some embodiments, the ECC transmitting headphone is primary wireless headphone 104, and the audio information is received by primary wireless headphone 104 via the normal communication link. In some embodiments, the ECC transmitting headphone is secondary wireless headphone 106, and the audio information is snooped by secondary wireless headphone 106 via the snoop communication link. In some embodiments, the transmitting headphone may transmit a first ACK message indicating that the audio information is received correctly to the audio source in response to successfully receiving the audio information.

At 708, an ECC is generated by the ECC transmitting headphone based on the audio information received by the ECC transmitting headphone in response to successfully receiving the audio information. The audio information may include an audio data packet (e.g., a BLUETOOTH audio data packet), and the error correcting code may be generated by coding a payload of the audio data packet. In some embodiments, control module 220 of primary wireless headphone 104 controls the coding of the payload when primary wireless headphone 104 is the ECC transmitting headphone. In some embodiments, control module 234 of secondary wireless headphone 106 controls the coding of the payload when secondary wireless headphone 106 is the ECC transmitting headphone.

At 710, a first error correcting message including the ECC but not the audio information is transmitted by the ECC transmitting headphone. The error correcting message may be transmitted based on a standard wireless communication protocol (e.g., a BLUETOOTH protocol) in network layers above a physical layer and transmitted at a higher symbol rate than the standard BLUETOOTH protocol in the physical layer. The first error correcting message may be transmitted using a second type of short-range wireless communication different from the first type of short-range wireless communication for transmitting the audio information. For example, the first type of short-range wireless communication is BLUETOOTH communication, and the second type of short-range wireless communication is WiFi communication or NFMI communication. In one example, a BLUETOOTH audio data packet and the first error correcting message are transmitted in the same time slot subsequently. In another example, a BLUETOOTH audio data packet is transmitted over multiple time slots, and the first error correcting message is transmitted at the end of the last one or more of the multiple time slots. In some embodiments, second RF module 212 of primary wireless headphone 104 transmits the first error correcting message when primary wireless headphone 104 is the ECC transmitting headphone. In some embodiments, second RF module 226 of secondary wireless headphone 106 transmits the first error correcting message when secondary wireless headphone 106 is the ECC transmitting headphone.

At 712, the audio information is received by the ECC receiving headphone from the audio source using the first type of short-range wireless communication, such as BLUETOOTH communication. In some embodiments, the ECC receiving headphone is primary wireless headphone 104, and the audio information is received by primary wireless headphone 104 via the normal communication link. In some embodiments, the ECC receiving headphone is secondary wireless headphone 106, and the audio information is snooped by secondary wireless headphone 106 via the snoop communication link.

At 714, the first error correcting message including the ECC is received by the ECC receiving headphone from the ECC transmitting headphone, for example, using the first type of short-range wireless communication, such as WiFi communication or NFMI communication.

At 716, the audio information received from the audio source at 712 is attempted to be corrected based on the first error correcting message by the ECC receiving headphone if the ECC receiving headphones detect error(s) in the audio information.

At 718, a second error correcting message including the audio information is transmitted by the ECC transmitting headphone to the ECC receiving headphone if the ECC receiving headphone detects the attempt to correct the received audio information is failed. In some embodiments, the second error correcting message may additionally include the ECC generated by coding the payload of the audio data packet. In some embodiments, the second error correcting message may be transmitted in the same manner as the first error correcting message being transmitted. For example, the second error correcting message may be transmitted based on a standard wireless communication protocol (e.g., a BLUETOOTH protocol) in network layers above a physical layer and transmitted at a higher symbol rate than the standard BLUETOOTH protocol in the physical layer. In some embodiments, the second error correcting message may be transmitted using a second type of short-range wireless communication different from the first type of short-range wireless communication for transmitting the audio information.

At 720, the second error correcting message including the ECC is received by the ECC receiving headphone from the ECC transmitting headphone, for example, using the first type of short-range wireless communication, such as WiFi communication or NFMI communication.

At 722, the audio information failed to be corrected at 716 based on the first error correcting message by the ECC receiving headphone is corrected by the ECC receiving headphones based on the second error correcting message that includes the audio information. The ECC receiving headphone then can successfully receive the audio information after the correction.

In some embodiments, in method 700, the ECC receiving headphone is further configured to transmit a NACK message to the ECC transmitting headphone indicating that the first error correcting message or the second error correcting message is not received correctly. In response to receiving the NACK message, the ECC transmitting headphone may re-transmit the first error correcting message or the second error correcting message until (i) the ECC transmitting headphone receives a second ACK message indicating that the ECC receiving headphone receives the first error correcting message or the second error correcting message correctly or (ii) the first error correcting message or the second error correcting message has been re-transmitted for more than a predetermined number of times. For one example, if the ECC transmitting headphone receives the NACK message indicating that the first error correcting message is not correctly received by the ECC receiving headphone, the ECC transmitting headphone may re-transmit the first error correcting headphone to the ECC receiving headphone until the ECC receiving headphone correctly receives the first error correcting message and transmit the second ACK message indicating that the first error correcting message has been received correctly. For another example, if the ECC transmitting headphone receives the NACK message indicating that the first error correcting message is not correctly received by the ECC receiving headphone, the ECC transmitting headphone may re-transmit the first error correcting headphone to the ECC receiving headphone until the first error correcting message has been re-transmitted for more than a predetermined number of times (e.g., 3 times, 5 times, or 10 times). The second error correcting message may be re-transmitted in a similar mechanism as is to re-transmit the first error correcting message.

FIG. 8 is another flow chart illustrating an exemplary method 800 for wirelessly communicating audio information in accordance with an embodiment. Method 800 can be performed by processing logic that can comprise hardware (e.g., circuitry, dedicated logic, programmable logic, microcode, etc.), software (e.g., instructions executing on a processing device), or a combination thereof. It is to be appreciated that not all operations may be needed to perform the disclosure provided herein. Further, some of the operations may be performed simultaneously, or in a different order than shown in FIG. 8, as will be understood by a person of ordinary skill in the art.

Method 800 shall be described with reference to FIGS. 1A, 1B, and 2. However, method 800 is not limited to that exemplary embodiment. Starting at 802, a first type of short-range wireless communication, such as BLUETOOTH communication, is established with an audio source. In some embodiments, the short-range wireless communication is established between primary wireless headphone 104 and audio source 102. At 804, communication parameters indicative of the short-range wireless communication are transmitted. In some embodiments, the communication parameters are transmitted from primary wireless headphone 104 to secondary wireless headphone 106 using the first type of short-range wireless communication, such as BLUETOOTH communication, or a second type of short-range wireless communication, such as WiFi communication or NFMI communication. In some other embodiments, the communication parameters may also be transmitted from secondary wireless headphone 106 to primary wireless headphone 104 using the first type or the second type of short-range wireless communication.

At 806, the audio information is received by an ECC transmitting headphone from the audio source using the first type of short-range wireless communication, such as BLUETOOTH communication. In some embodiments, the audio information may include a header and a payload. In some embodiments, the ECC transmitting headphone is primary wireless headphone 104, and the audio information is received by primary wireless headphone 104 via the normal communication link. In some embodiments, the ECC transmitting headphone is secondary wireless headphone 106, and the audio information is snooped by secondary wireless headphone 106 via the snoop communication link.

At 808, the audio information is received by an ECC receiving headphone from the audio source using the first type of short-range wireless communication, such as BLUETOOTH communication. In some embodiments, the ECC receiving headphone is primary wireless headphone 104, and the audio information is received by primary wireless headphone 104 via the normal communication link. In some embodiments, the ECC receiving headphone is secondary wireless headphone 106, and the audio information is snooped by secondary wireless headphone 106 via the snoop communication link.

In some embodiments, the ECC transmitting headphone and the ECC receiving headphone may be dynamically switched between primary wireless headphone 104 and secondary wireless headphone 106 based on a signal quality of each of the ECC transmitting headphone and the ECC receiving headphone. For example, the ECC transmitting headphone is always the wireless headphone with better signals.

At 810, the ECC receiving headphone determines if it receives the audio information correctly. At 812, if the ECC receiving headphone correctly receives the audio information, a first ACK message indicating the ECC receiving headphone receives both the header and the payload of the audio information correctly will be transmitted to the ECC transmitting headphone.

At 814, an ECC is generated by the ECC transmitting headphone based on the audio information received by the ECC transmitting headphone if the ECC receiving headphone determines it does not receive the audio information correctly. The error correcting code may be generated by coding a payload of the audio data packet of the audio information. In some embodiments, control module 220 of primary wireless headphone 104 controls the coding of the payload when primary wireless headphone 104 is the ECC transmitting headphone. In some embodiments, control module 234 of secondary wireless headphone 106 controls the coding of the payload when secondary wireless headphone 106 is the ECC transmitting headphone.

At 816, in response to the ECC receiving headphone determines that it does not correctly receive the audio information, the ECC receiving headphone further determines if it receives the header of the audio information correctly.

At 818 a first NACK message indicating the ECC receiving headphone receives the header, but not the payload of the audio information correctly is generated and transmitted to the ECC transmitting headphone if the ECC receiving headphone determines it receives the header of the audio information correctly.

At 820, a first error correcting message including the ECC but not the audio information is transmitted by the ECC transmitting headphone in response to the ECC receiving headphone receives the header, but not the payload, of the audio information correctly. The error correcting message may be transmitted based on a standard wireless communication protocol (e.g., a BLUETOOTH protocol) in network layers above a physical layer and transmitted at a higher symbol rate than the standard BLUETOOTH protocol in the physical layer. The first error correcting message may be transmitted using a second type of short-range wireless communication different from the first type of short-range wireless communication for transmitting the audio information. For example, the first type of short-range wireless communication is BLUETOOTH communication, and the second type of short-range wireless communication is an amended BLUETOOTH communication, a WiFi communication or an NFMI communication. In one example, a BLUETOOTH audio data packet and the first error correcting message are transmitted in the same time slot subsequently. In another example, a BLUETOOTH audio data packet is transmitted over multiple time slots, and the first error correcting message is transmitted at the end of the last one or more of the multiple time slots. In some embodiments, second RF module 212 of primary wireless headphone 104 transmits the error correcting message when primary wireless headphone 104 is the ECC transmitting headphone. In some embodiments, second RF module 226 of secondary wireless headphone 106 transmits the error correcting message when secondary wireless headphone 106 is the ECC transmitting headphone.

At 822 a second NACK message indicating the ECC receiving headphone does not receive the header nor the payload of the audio information correctly is generated and transmitted to the ECC transmitting headphone if the ECC receiving headphone determines it does not receive the header of the audio information correctly.

At 824, a second error correcting message including the audio information is transmitted by the ECC transmitting headphone in response to the ECC transmitting headphone receives the second NACK. In some embodiments, the second error correcting message may additionally include the error correcting code generated by coding a payload of the audio data packet. In some embodiments, the second error correcting message may be transmitted in the same manner as the first error correcting message being transmitted.

In some embodiments, in method 800, the ECC receiving headphone is further configured to transmit a third NACK message to the ECC transmitting headphone indicating that the first error correcting message or the second error correcting message is not received correctly. In response to receiving the third NACK message, the ECC transmitting headphone may re-transmit the first error correcting message or the second error correcting message until (i) the ECC transmitting headphone receives a second ACK message indicating that the ECC receiving headphone receives the first error correcting message or the second error correcting message correctly or (ii) the first error correcting message or the second error correcting message has been re-transmitted for more than a predetermined number of times. For one example, if the ECC transmitting headphone receives the third NACK message indicating that the first error correcting message is not correctly received by the ECC receiving headphone, the ECC transmitting headphone may re-transmit the first error correcting headphone to the ECC receiving headphone until the ECC receiving headphone correctly receives the first error correcting message and transmit the second ACK message indicating that the first error correcting message has been received correctly. For another example, if the ECC transmitting headphone receives the third NACK message indicating that the first error correcting message is not correctly received by the ECC receiving headphone, the ECC transmitting headphone may re-transmit the first error correcting headphone to the ECC receiving headphone until the first error correcting message has been re-transmitted for more than a predetermined number of times (e.g., 3 times, 5 times, or 10 times). The second error correcting message may be re-transmitted in a similar mechanism as is to re-transmit the first error correcting message.

FIG. 9 is a flow chart illustrating still another exemplary method 900 for wirelessly communicating audio information in accordance with an embodiment. Method 900 can be performed by processing logic that can comprise hardware (e.g., circuitry, dedicated logic, programmable logic, microcode, etc.), software (e.g., instructions executing on a processing device), or a combination thereof. It is to be appreciated that not all operations may be needed to perform the disclosure provided herein. Further, some of the operations may be performed simultaneously, or in a different order than shown in FIG. 9, as will be understood by a person of ordinary skill in the art.

Method 900 may be performed by whichever wireless headphone that fails to receive the audio information correctly and also fails to correct the audio information based on a first error correcting message disclosed herein regardless of whether it is primary wireless headphone 104 or secondary wireless headphone 106. Starting at 902, a first type of short-range wireless communication is established with an audio source. In some embodiments, the short-range wireless communication is established between primary wireless headphone 104 and audio source 102. At 904, communication parameters indicative of the short-range wireless communication are transmitted. In some embodiments, the communication parameters are transmitted from primary wireless headphone 104 to secondary wireless headphone 106 using the first type of short-range wireless communication, such as BLUETOOTH communication, or a second type of short-range wireless communication, such as WiFi communication or NFMI communication. In some other embodiments, the communication parameters may also be transmitted from secondary wireless headphone 106 to primary wireless headphone 104 using the first type or the second type of short-range wireless communication. With the parameter, the receiving wireless headphone may snoop and/or receive audio information from audio source 102.

At 906, the audio information is received by both primary wireless headphone 104 and second wireless headphone 106 from the audio source using the first type of short-range wireless communication. At 908, both primary wireless headphone 104 and second wireless headphone 106 transmit a first error correcting message including an ECC by coding the payload of the BLUETOOTH audio data packet of the audio information to the other wireless headphone for correcting errors in the audio packet of the audio information. At 910, in case where one of primary wireless headphone 104 or second wireless headphone 106 fails to correct errors in the audio packet of the audio information, the wireless headphone receives a second error correcting message including the audio information from the other wireless headphone for correcting errors in the audio packet of the audio information. In some embodiments, the second error correcting message may additionally include the ECC generated by coding a payload of the audio data packet.

FIG. 10 is a flow chart illustrating still another exemplary method 1000 for wirelessly communicating audio information in accordance with an embodiment. Method 1000 can be performed by processing logic that can comprise hardware (e.g., circuitry, dedicated logic, programmable logic, microcode, etc.), software (e.g., instructions executing on a processing device), or a combination thereof. It is to be appreciated that not all operations may be needed to perform the disclosure provided herein. Further, some of the operations may be performed simultaneously, or in a different order than shown in FIG. 10, as will be understood by a person of ordinary skill in the art.

Method 1000 may be performed by a determining headphone disclosed herein regardless of whether it is primary wireless headphone 104 or secondary wireless headphone 106. Starting at 1002, a first type of short-range wireless communication is established with an audio source. In some embodiments, the short-range wireless communication is established between primary wireless headphone 104 and audio source 102. At 1004, communication parameters indicative of the short-range wireless communication are transmitted. In some embodiments, the communication parameters are transmitted from primary wireless headphone 104 to secondary wireless headphone 106 using the first type of short-range wireless communication, such as BLUETOOTH communication, or a second type of short-range wireless communication, such as WiFi communication or NFMI communication. In some other embodiments, the communication parameters may also be transmitted from secondary wireless headphone 106 to primary wireless headphone 104 using the first type or the second type of short-range wireless communication. With the parameter, the receiving wireless headphone may snoop and/or receive audio information from audio source 102.

At 1006, the audio information is received by both primary wireless headphone 104 and second wireless headphone 106 from the audio source using the first type of short-range wireless communication. At 1008, both primary wireless headphone 104 and second wireless headphone 106 determines if it receives the audio information correctly. At 1010, if the determining headphone determines that it correctly receives the audio information, a first ACK message indicating the determining headphone receives both the header and the payload of the audio information correctly will be transmitted to the other headphone.

At 1012, the determining headphone further determines if it receives the header of the audio information correctly in response to the determining headphone determines that it does not correctly receive the audio information. At 1014, a first NACK message indicating the determining headphone receives the header, but not the payload of the audio information correctly is generated and transmitted to the other headphone if the determining headphone determines it receives the header of the audio information correctly. At 1016, a first error correcting message including the ECC generated by coding a payload of the audio data packet of the audio information but not the audio information is transmitted by the determining headphone in response to the determining headphone receives the header, but not the payload, of the audio information correctly. At 1018, a second NACK message indicating the determining headphone does not receive the header nor the payload of the audio information correctly is generated and transmitted to the other headphone if the determining headphone determines it does not receive the header of the audio information correctly. At 1020, a second error correcting message including the audio information is transmitted by the determining headphone in response to the other headphone receives the second NACK. In some embodiments, the second error correcting message may additionally include the ECC generated by coding a payload of the audio data packet.

It is understood that all the error correcting messages including the audio information disclosed herein may additionally include the ECC generated by coding the payload of an audio data packet. In other words, the difference between the first error correcting messages and the second error correcting messages may only be whether it includes the audio information.

It is to be appreciated that the Detailed Description section, and not the Summary and Abstract sections, is intended to be used to interpret the claims. The Summary and Abstract sections may set forth one or more but not all exemplary embodiments of the present disclosure as contemplated by the inventor(s), and thus, are not intended to limit the present disclosure or the appended claims in any way.

While the present disclosure has been described herein with reference to exemplary embodiments for exemplary fields and applications, it should be understood that the present disclosure is not limited thereto. Other embodiments and modifications thereto are possible, and are within the scope and spirit of the present disclosure. For example, and without limiting the generality of this paragraph, embodiments are not limited to the software, hardware, firmware, and/or entities illustrated in the figures and/or described herein. Further, embodiments (whether or not explicitly described herein) have significant utility to fields and applications beyond the examples described herein.

Embodiments have been described herein with the aid of functional building blocks illustrating the implementation of specified functions and relationships thereof. The boundaries of these functional building blocks have been arbitrarily defined herein for the convenience of the description. Alternate boundaries can be defined as long as the specified functions and relationships (or equivalents thereof) are appropriately performed. Also, alternative embodiments may perform functional blocks, steps, operations, methods, etc. using orderings different than those described herein.

The breadth and scope of the present disclosure should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents. 

What is claimed is:
 1. A wireless audio system, comprising: A first wireless headphone configured to: receive, from an audio source, audio information using a short-range wireless communication; and in response to successfully receiving the audio information from the audio source, transmit a first error correcting message comprising an error correcting code generated based on the audio information to a second wireless headphone; and the second wireless headphone configured to: receive the audio information from the audio source using the short-range wireless communication; attempt to correct the received audio information based on the first error correcting message; and determine that the received audio information fails to be corrected; and wherein in response to the determination, the first wireless headphone is further configured to transmit a second error correcting message comprising the received audio information to the second wireless headphone.
 2. The wireless audio system of claim 1, wherein the first wireless headphone is further configured to transmit communication parameters associated with the short-range wireless communication to the second wireless headphone to enable the second wireless headphone to receive the audio information from the audio source based on the communication parameters;
 3. The wireless audio system of claim 1, wherein: the second wireless headphone is further configured to transmit a negative acknowledgment (NACK) message to the first wireless headphone indicating that the first error correcting message or the second error correcting message is not received correctly; and the first wireless headphone is further configured to, in response to receiving the NACK message, re-transmit the first error correcting message or the second error correcting message until (i) the first wireless headphone receives an acknowledgement (ACK) message from the second wireless headphone indicating that the second wireless headphone receives the first error correcting message or the second error correcting message correctly, or (ii) the first error correcting message or the second error correcting message has been re-transmitted for more than a predetermined number of times.
 4. The wireless audio system of claim 1, wherein: the audio information includes a BLUETOOTH audio data packet; and the error correcting code is generated by coding a payload of the BLUETOOTH audio data packet.
 5. The wireless audio system of claim 1, wherein the second error correcting message further comprises the error correcting code.
 6. The wireless audio system of claim 1, further comprising a plurality of short-range wireless communication links working at different frequencies between the first and the second wireless headphones.
 7. The wireless audio system of claim 1, wherein in response to successfully receiving the audio information, the first wireless headphone is further configured to transmit, to the audio source, a first ACK message indicating that the audio information is received correctly.
 8. The wireless audio system of claim 7, wherein in response to the first wireless headphone not transmitting the first ACK message to the audio source, the second wireless headphone is further configured to transmit a second ACK message to the audio source in response to the second wireless headphone correcting the received audio information based on the first error correcting message or the second error correcting message.
 9. A wireless audio system, comprising: a first wireless headphone configured to receive, from an audio source, audio information comprising a header and a payload using a short-range wireless communication; and a second wireless headphone configured to: receive the audio information from the audio source using the short-range wireless communication; transmit at least one of a first ACK message indicating the second wireless headphone receives the header and the payload of the audio information correctly, a first NACK message indicating the second wireless headphone receives the header, but not the payload, of the audio information correctly, or a second NACK message indicating the second wireless headphone does not receive the header and the payload of the audio information correctly to the first wireless headphone; wherein the first wireless headphone is further configured to: receive the at least one of the first ACK message, the first NACK message and the second NACK message; transmit, to the second wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information in response to receiving the first NACK message; and transmit, to the second wireless headphone, a second error correcting message comprising the received audio information in response to receiving the second NACK message.
 10. The wireless audio system of claim 9, wherein the first wireless headphone is further configured to transmit communication parameters associated with the short-range wireless communication to the second wireless headphone to enable the second wireless headphone to receive the audio information from the audio source based on the communication parameters.
 11. The wireless audio system of claim 9, wherein: the second wireless headphone is further configured to transmit a third NACK message to the first wireless headphone indicating that the first error correcting message or the second error correcting message is not received correctly; and wherein the first wireless headphone is further configured to, in response to receiving the third NACK message, re-transmit the first error correcting message or the second error correcting message until (i) the first wireless headphone receives a second ACK message indicating that the second wireless headphone receives the first error correcting message or the second error correcting message correctly or (ii) the first error correcting message or the second error correcting message has been re-transmitted for more than a predetermined number of times.
 12. The wireless audio system of claim 9, wherein the second error correcting message further comprises the error correcting code.
 13. The wireless audio system of claim 9, wherein the first and second wireless headphones are configured to be dynamically switched based on a signal quality of each of the first and the second wireless headphones.
 14. The wireless audio system of claim 9, further comprising a plurality of short-range wireless communication links working at different frequencies between the first and the second wireless headphones.
 15. The wireless audio system of claim 14, wherein the plurality of short-range wireless communication links comprise at least one of BLUETOOTH communication, BLUETOOTH Low Energy communication, amended BLUETOOTH communication, Wi-Fi communication, or Near-Field Magnetic Induction communication (NFMI) communication.
 16. A method for wirelessly communicating audio information, comprising: receiving, by a first wireless headphone, audio information using a short-range wireless communication from an audio source; in response to successfully receiving the audio information from the audio source, transmitting, by the first wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information to a second wireless headphone; receiving, by the second wireless headphone, the audio information from the audio source using the short-range wireless communication; attempting, by the second wireless headphone, to correct the received audio information based on the first error correcting code; determining, by the second wireless headphone, that the received audio information fails to be corrected; and in response to the determination, transmitting, by the first wireless headphone, a second error correcting message comprising the received audio information to the second wireless headphone.
 17. The method of claim 16 further comprising dynamically switching the first and second wireless headphones based on a signal quality of each of the first and second wireless headphones.
 18. The method of claim 16 further comprising transmitting, communication parameters associated with the short-range wireless communication, by the first wireless headphone to the second wireless headphone to enable the second wireless headphone to receive the audio information from the audio source based on the communication parameters.
 19. The method of claim 16 further comprising transmitting, by the first wireless headphone, an ACK message to the audio source in response to the first wireless headphone correctly receive the audio information.
 20. The method of claim 16, wherein the first error correcting message and the second error correcting message are transmitted in different packets.
 21. A method for wirelessly communicating audio information, comprising: receiving, by a first wireless headphone, audio information comprising a header and a payload using a short-range wireless communication from an audio source; receiving, by a second wireless headphone, the audio information from the audio source using the short-range wireless communication; transmitting, by the second wireless headphone to the first wireless headphone, at least one of an ACK message indicating the second wireless headphone receives the header and the payload of the audio information correctly, a first NACK message indicating the second wireless headphone receives the header, but not the payload, of the audio information correctly, or a second NACK message indicating the second wireless headphone does not receive the header nor the payload of the audio information correctly; transmitting, by the first wireless headphone to the second wireless headphone, a first error correcting message comprising an error correcting code generated based on the audio information in response to the first wireless headphone receives the first NACK message; and transmitting, by the first wireless headphone to the second wireless headphone, a second error correcting message comprising the received audio information in response to the second wireless headphone receives the first NACK message.
 22. The method of claim 21 further comprising transmitting, by the first wireless headphone to the second wireless headphone, parameters associated with the short-range wireless communication, to enable the second wireless headphone to receive the audio information from the audio source based on the communication parameters.
 23. The method of claim 21 further comprising dynamically switching the first wireless headphone and second wireless headphone based on a signal quality of each of the first wireless headphone and the second wireless headphone. 